Correlation Between Dysplasia and Ploidy Status in Oral Leukoplakia

Zyl, Andre W. Van; Heerden, Marlene B. van; Langenegger, Emil; Heerden, W.F.P. Van

doi:10.1007/s12105-012-0352-9

Cited by 29 publications

(20 citation statements)

References 18 publications

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“…Preneoplastic oral epithelium is usually aneuploid (8)(9)(10) and DNA aneuploidy indicates risk of malignant transformation (11). These changes can be measured using karyometry, flow cytometry (12), and image analysis (13) and more subtle loss of heterozygosity by molecular methods (14).…”

Section: Introductionmentioning

confidence: 99%

Predictive Value of Dysplasia Grading and DNA Ploidy in Malignant Transformation of Oral Potentially Malignant Disorders

Sperandio

Brown

Lock

et al. 2013

Cancer Prevention Research

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Dysplasia grading is widely used to assess risk of transformation in oral potentially malignant disorders despite limited data on predictive value. DNA ploidy analysis has been proposed as an alternative. This study examines the prognostic value for both tests used in a routine diagnostic setting to inform clinical management. A retrospective study of conventional dysplasia grading was conducted on 1,401 patients. DNA ploidy analysis was conducted on a subset of 273 patients and results correlated with clinical information, pathologic diagnosis, and outcome over 5 to 15 years.Malignant transformation occurred in 32 of 273 patients (12%) and, of these, 20 (63%) of preexisting index lesions were aneuploid. Of 241 patients not developing carcinoma, only 39 (16%) of index lesions were aneuploid. Epithelial dysplasia correlated with DNA ploidy status (P < 0.001). The overall positive predictive value for malignant transformation by DNA aneuploidy was 38.5% (sensitivity 65.2% and specificity 75%) and by severe dysplasia grade 39.5% (sensitivity 30% and specificity 98%). DNA diploid and tetraploid status had negative predictive value of 90% to 96%. Combining DNA ploidy analysis with dysplasia grading gives a higher predictive value than either technique alone.Each of three traditional dysplasia grades predicts a significantly different risk of carcinoma development and time to transformation. DNA ploidy analysis had equivalent predictive value and also detected additional risk lesions in the absence of dysplasia. Cancer Prev Res; 6(8); 822-31. Ó2013 AACR.

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Section: Introductionmentioning

confidence: 99%

Predictive Value of Dysplasia Grading and DNA Ploidy in Malignant Transformation of Oral Potentially Malignant Disorders

Sperandio

Brown

Lock

et al. 2013

Cancer Prevention Research

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“…Furthermore, individuals with Down syndrome carrying an extra copy of chromosome 21 have a 50% lower risk of developing a solid tumor but a significantly higher risk of developing leukemia, as compared to individuals with a normal karyogram (Hasle et al, 2000). On the other hand, aneuploidy is an early event found in typical pre-cancer stages such as cervix dysplasia, Barrett esophagus, leukoplakia and bronchus dysplasia (Sandritter, 1965; Reid et al, 2000; Hanselmann and Oberringer, 2001; Lothschütz et al, 2002; van Zyl et al, 2012) liver cirrhosis (Attallaha et al, 1999) and others (Bohm and Sandritter, 1975). It is interesting that aneuploidy is even detectable in chronic inflammatory tissue such as wounds (Ermis et al, 1998; Oberringer et al, 1999) and inflammatory bronchial tissue (Hanselmann and Oberringer, 2001; Lothschütz et al, 2002), after acute and chronic hypoxic conditions (Ueyama et al, 2012; Kondoh et al, 2013), and after exposure to physical (Grosovsky et al, 1996; Kirsch-Volders et al, 1996) or chemical stressors (Galloway and Ivett, 1986; Mattiuzzo et al, 2006; Tayama et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Origin of Cancer: An Information, Energy, and Matter Disease

Hanselmann

Welter

2016

Front. Cell Dev. Biol.

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Cells are open, highly ordered systems that are far away from equilibrium. For this reason, the first function of any cell is to prevent the permanent threat of disintegration that is described by thermodynamic laws and to preserve highly ordered cell characteristics such as structures, the cell cycle, or metabolism. In this context, three basic categories play a central role: energy, information, and matter. Each of these three categories is equally important to the cell and they are reciprocally dependent. We therefore suggest that energy loss (e.g., through impaired mitochondria) or disturbance of information (e.g., through mutations or aneuploidy) or changes in the composition or distribution of matter (e.g., through micro-environmental changes or toxic agents) can irreversibly disturb molecular mechanisms, leading to increased local entropy of cellular functions and structures. In terms of physics, changes to these normally highly ordered reaction probabilities lead to a state that is irreversibly biologically imbalanced, but that is thermodynamically more stable. This primary change—independent of the initiator—now provokes and drives a complex interplay between the availability of energy, the composition, and distribution of matter and increasing information disturbance that is dependent upon reactions that try to overcome or stabilize this intracellular, irreversible disorder described by entropy. Because a return to the original ordered state is not possible for thermodynamic reasons, the cells either die or else they persist in a metastable state. In the latter case, they enter into a self-driven adaptive and evolutionary process that generates a progression of disordered cells and that results in a broad spectrum of progeny with different characteristics. Possibly, 1 day, one of these cells will show an autonomous and aggressive behavior—it will be a cancer cell.

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“…The role of DNA aneuploidy as a potential biomarker of early oral carcinogenesis and tumour progression has been investigated by means of both image and flow cytometry with promising results, mainly addressing oral leukoplakia and lesions with dysplasia (Pentenero et al, 2009;Torres-Rendon et al, 2009;Bradley et al, 2010;Bremmer et al, 2011;Brouns et al, 2012;van Zyl et al, 2012;Sperandio et al, 2013). Several studies also addressed DNA ploidy in OLP with contrasting results: some found no occurrence at all (Rode et al, 2006;Neppelberg and Johannessen, 2007;Acha-Sagredo et al, 2011;Sperandio et al, 2013), while others reported a substantial DNA aneuploidy rate of about 27-28% (Yarom et al, 2009;Hosni et al, 2010;Chitturi et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

High‐resolution DNA content analysis of microbiopsy samples in oral lichen planus

et al. 2016

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DNA aneuploidy is an uncommon event in OLP and less frequent compared to other non-dysplastic and non-OLP oral potentially malignant disorders. The extremely low rate of DNA aneuploidy could represent an occasional finding or reflect the low rate of malignant transformation observed in patients with OLP even if the real prognostic value of DNA ploidy analysis in patients with OLP remains to be confirmed.

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Correlation Between Dysplasia and Ploidy Status in Oral Leukoplakia

Cited by 29 publications

References 18 publications

Predictive Value of Dysplasia Grading and DNA Ploidy in Malignant Transformation of Oral Potentially Malignant Disorders

Predictive Value of Dysplasia Grading and DNA Ploidy in Malignant Transformation of Oral Potentially Malignant Disorders

Origin of Cancer: An Information, Energy, and Matter Disease

High‐resolution DNA content analysis of microbiopsy samples in oral lichen planus

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